Vertical slab gel electrophoresis cell and method therefor

ABSTRACT

In the present innovations on vertical slab gel electrophoresis cell and method, 6 embodiments embodied 3 different mechanisms for urging the cassettes to abut the upper buffer chamber, every of them has its merit; a dual-gel cell allows not to block up the other side opening when one gel runs in it; all cassettes are formed by rectangular sidewalls and fringed spacer strips, but still can form a U-notched upper opening with even rim for every cassette, 2 kind cassettes can undergo the gel casting within the electrophoresis cell, other 2 kind cassettes can form an unlimited cassette/UBC complex; a cooling device needs not exogenous coolant; disclosed 4 convenient methods can snugly encase almost all kind cassettes into membrane pouches for perform homogeneous or gradient gel casting.

BACKGROUND

[0001] 1. Field of Invention

[0002] This invention relates to electrophoresis equipment and method, and specifically to improved vertical slab gel electrophoresis equipment and related methods.

[0003] 2. Prior Art and Comment

[0004] Ferdinand Ruess, a Russian physicist, watched the migration of clay colloidal particles between two electrodes in 1897. About 50 years later, Arne Tiselius, a Swedish chemist, studied the migration of protein molecules in electric field, demonstrated the complex nature of serum proteins by using a prototype that he termed as a free electrophoresis apparatus. Whereby he won the Nobel Prize for chemistry of 1948. Electrophoresis has now become a versatile and powerful technique in biomedical and related research areas. It can be employed to fractionalize almost any charged particle, from ionizable small molecules to whole cells. When an electrophoresis carries out in a gel matrix, it terms as gel electrophoresis. Gel electrophoresis has very high resolution, is mainly employed to fractionate biomacromolecular species, such as DNA, RNA or proteins. That is because the network of the gel matrix acts as a molecular sieve to retard the migration of the macromolecular species according to their size and shape. Besides, the gel matrix can also stabilize the boundaries of the separated species both during and after the electrophoresis, so as to facilitate the subsequent analyses. The widely employed gel matrixes are agarose gel and polyacrylamide gel. The latter can be cast into a vertical cavity due to it can adhere better to the cavity walls. By successfully exploited the high fractionation ability of vertical slab polyacrylamide gel electrophoresis for determination the base sequences of DNA, Frederick Sanger, a British biochemist, and his American colleague Walter Gilbert were awarded the Nobel Prize for chemistry of 1980.

[0005] In vertical slab gel electrophoresis (abbreviated as VSGE hereafter), the electrophoretic vector travels vertically within a slab shaped gel matrix uprightly arranged between an upper and a lower pH buffer solution chambers charged with opposite electrodes. Usually the gel slab is only 0.2 to 2.0 mm in thickness. None such a gel slab can stand uprightly by itself unless it is held in a cassette; none such a gel slab can be properly held in a cassette unless it is directly cast and formed in it. Therefore, and obviously, there are three basic problems regarding the design of any VSGE cell: (i) how to construct a vertical slab gel casting cassette (abbreviated as VSGC cassette, gel casting cassette, or cassette hereafter) having sealed left and right edges but opened up and low ends; (ii) how to insure a gel matrix to be cast into the cassette without leakage; and (iii) how to urge the cassette to water-tightly join the upper buffer chamber (abbreviated as UBC hereafter) with the upper opening of the cassette exposes into the formed cassette/UBC complex. As long as the cassette/UBC complex forms, just sets it into a lower buffer chamber (abbreviated as LBC thereafter), thereupon a VSGE cell is accomplished. As for how to arrange the electrodes in the UBC and LBC, and how to make a lid for the VSGE cell, those are foolproof.

[0006] About the size: Typically there were three different sized VSGE cells. The 36×30 cm slab gels were usually used for DNA sequencing electrophoresis. But it has been replaced by some automatic capillary gel electrophoresis instruments in the developed countries, referring to U.S. Pat. No. 5,374,527 (1994), etc. The 18×16 cm slab gels were widely used for protein fractionation in the early years. However nowadays, more than 95% chance is to run the mini gel, which casts in 8×10, or 10×10 cm cassettes, due to its shorter running time and easer to manipulate.

[0007] About the structure style: There were several different styled VSGE cells, referring to U.S. Pat. No. 3,719,580 (1973), U.S. Pat. No. 4,224,134 (1980) and U.S. Pat. No. 4,574,040 (1986), etc. However, the most popular styled VSGE cell is a kind of dual gel cell, which was initiated by Madjar et al (1) in 1977. Thereafter various VSGE cells were patented, but most of them wore still belong to the most popular styled dual gel cell as mentioned above, referring to U.S. Pat. No. 4,574,040 (1986), U.S. Pat. No. 5,632,877 (1997), U.S. Pat. Nos. 5,888,369 and 6,001,233 (1999), etc. Their common structure style is that; on one hand, making the UBC to have two opposite U-shaped side openings; on the other hand, making each cassette to have a U-notched upper opening; and then using an urging mechanism to force those two cassettes to sandwich that UBC between them. Certainly, U-shaped rubber sealing-gaskets are always employed for sealing up the interfaces between the cassettes and UBC. As a result, a water-tightly joined cassettes/UBC complex is formed with the two U-notched upper openings naturally expose into the formed complex. However, their common weakness is that when only one gel runs in such a dual gel cell, the other side opening of the UBC has to be blocked up. It is inconvenient, because more than 50% chance is to run one gel a time. In CN Pat. 88106198.0 (1982), the inventor developed a modular VSGE cell, which allows numerous slab gels to run in it parallel.

[0008] About the cassette: compare with any kind plastic, glass plate is a better material to wall VSGC cassettes, due to it has much higher rigidity, much higher chemical inertness, much higher thermal conductivity; and exceptionally due to the gel matrix can adhere it better. Ceramic, such as aluminum oxide plate, is even better than glass, but it is not transparent and cannot be as cheap as glass plate. Unfavorably, both of them are typical bad machining-able materials, so that to make glass and/or ceramic walled cassettes can never be as easy as to make them by plastics. Nevertheless, any reusable cassette is had better to be glass and/or ceramic walled by the reason as mentioned above. The simplest glass walled cassettes was formed by two identical rectangular glass plates and a pair of flat plastic spacer strip, as reported by Herbert Tichy (2) in 1966. However, this kind cassette is not easy to join the UBC, and its sample loading area is not easy to access, referring to U.S. Pat. No. 4,224,134 (1980). Afterward, one of the two rectangular glass plates was replaced by a U-notched glass plate, so as to make the cassette having a U-notched upper opening, referring to the report of F. W. Studier (3) in 1973. However, the U-notched glass or ceramic plates are much more costly and much more fragile than rectangular plates. Subsequently, the U-notched glass wall was replaced back by a shorter rectangular glass wall, as in U.S. Pat. No. 4,574,040. Although the shorter glass wall along with two flat plastic spacer strips also can form a U-notched upper opening for the cassette, but this way formed U-notched upper opening does not have an even rim. As a result, the leakage of the upper pH buffer solution becomes the major problem if this kind cassette is employed in any VSGE cell, referring to the Tech Note (4). Cross section T-shaped spacer strips were used to form a cassette in U.S. Pat. No. 4,560,459 (1985), but that cassette still had to use a U-notched sidewall. A three-element cassette was disclosed in U.S. Pat. No. 4,954,236 (1990), but its abutting face has no even margin to insure a leak-free abutting.

[0009] Besides, a fact was examined in the prior art. That is under appropriate pressure, the left and right margins of those glass walled VSGE cassettes could achieve leak-free, provided the employed two plastic spacer strips are wide and smooth enough, therefore makes no need using grease or glue to seal up the left and right margins.

[0010] About the urging mechanism: An urging mechanism is always required for forcing the cassette and the UBC to rest on each other tightly. Most employed urging mechanisms were too complex and lax, so that large LBC were always required, refereeing to U.S. Pat. No. 4,574,040 (1986), U.S. Pat. No. 5,632,877 (1997) and U.S. Pat. Nos. 5,888,369, 6,001,233 (1999), etc. A compact clamp urging mechanism was disclosed recently in U.S. Pat. No. 6,436,262 (2002), but it looks short of compatibility.

[0011] About the gel casting: Essentially the process of gel casting is same to the process of the Plexiglas plate manufacturing, as disclosed in U.S. Pat. No. 2,154,639 (1939) of Rohm et al. However, herein the formed polymer is a hydrophilic gel matrix, is not supposed to be moved out off the mold for any other use, but is for stay in situ as a matrix for an electrophoresis to take place therein. Most ordinary VSGC cassettes can be arranged in face to face, put into a gel-casting box to perform gel casting. The first gel casting box, and the method of gradient slab gel casting was reported by Margolis et al (5) in 1968. Different size, different improved gel casting boxes are commercially available nowadays. However, their common defect is lacking of flexibility. Extraterrestrial G. P. Magnant patented a casting method for forming a gel matrix in U.S. Pat. No. 5,188,790 (1993). However since several thousand years ago, our human being already knew how to form objects by casting. The chemical mechanism of the polyacrylamide gel formation for electrophoresis was published by Leonard Ornstein (6) in 1964. Of course, any kind of casting needs a mold. If Magnant patented apparatuses is a three-element assembled mold, it had been disclosed by Rohm et al 54 years ago before him. Even though, the problem is how to carry out an electrophoresis in such a three-element mold, which has no lower opening. Overlooking of all other problems, and if there is no misunderstood to us, then the patented method of Magnate seems nothing more than putting a ordinary cassette into a ordinary loose plastic membrane bag, and then using four objects from four sides to push the loose bag towards the cassette for gel casting. If so, Magnant patented method looks neither convenient nor flexible than using those gel casting boxes. Several different methods were designed to seal up the lower openings of VSGC cassettes for gel casting, referring to U.S. Pat. No. 4,224,134 (1980), U.S. Pat. No. 5,192,408 (1993), U.S. Pat. No. 5,520,790 (1996), U.S. Pat. Nos. 6,110,340 and 6,162,342 (2000), etc. But most of them have no compatibility, some are not dependable, some are inconvenient.

[0012] About the heat absorbing device: Joule-heating generates in the gel matrix during electrophoresis. A heat-absorbing device is required in a VSGE cell when the samples need to run in native state. However in most cases, such as in DNA sequencing gel electrophoresis or SDS protein gel electrophoresis, the samples need to run in denatured state, therefore making no heat-absorbing device is required. All heat-absorbing devices in the prior art need to use exogenous coolant, referring to U.S. Pat. No. 4,224,134 (1980) and U.S. Pat. No. 4,574,040 (1986), etc.

SUMMARY

[0013] According to the present innovates, almost all aspects of VSGE cell and the related method have been improved; wherein 6 embodiments embodied 3 different mechanisms for urging the cassette to abut to the UBC, each of them has its merit; a dual gel cell allows not to block up the other side opening when a single gel runs in it; all cassettes are formed by rectangular sidewalls and fringed spacer strips, but still can form a U-notched upper opening with even rim for every cassette; two kind cassettes can undergo the gel casting within the VSGE cell, other two kind cassettes can form an unlimited cassette/UBC complex, which is ideal for the 2-D electrophoresis; a cooling device needs not exogenous coolant; improved rubber sealing-gasket has higher elasticity and higher compatibility to thickness different cassettes; disclosed four convenient methods can snugly encase almost all kind cassettes into membrane pouch for performing homogeneous or gradient gel casting.

OBJECTS AND ADVANTAGES

[0014] Accordingly, the objects and advantages of the present invention are:

[0015] (a) planting a septum wall or a cooling chamber into a UBC, raising up the altitude of the electrodes in it, and using a shallower LBC, so as to allow unnecessary blocking up the other side opening when a single gel runs in such a dual gel cell;

[0016] (b) equipping a swing-frame aside each U-shaped side opening of the UBC; swung-open it allowing a cassette to insert therebetween; swing-close it can urge the cassette to abut the UBC tightly; this mechanism is novel, compact, flexible and easy to operate;

[0017] (c) arranging a UBC along with two cassettes into a right angle trapezoidal apron, thus a V-shaped gap is formed therebetween; to push a cylinder-beam into the V-shaped gap can urge the cassette(s) to abut the UBC tightly; this mechanism is also novel, compact, flexible and easy to operate;

[0018] (d) holding a cam-beam aside a cassette, which faces a U-shaped side opening of the UBC; turn-close the cam-beam also can urge the cassette to abut the UBC tightly; this mechanism his nothing to do with the LBC;

[0019] (e) persisting in using glass and/or ceramic plates to wall the VSGC cassettes, so as to make the formed cassettes has higher rigidity, better heat dissipation, and allows the gel matrix to adhere better to the cassette walls;

[0020] (f) using non-notched side walls and flanged spacer strips to form all cassettes, but still can form a U-notched upper opening with even rim for every cassette, so as to insure a leak-free abutting to the UBC, and can significantly reduce the cost and the fragility of the cassettes;

[0021] (g) two kind cassettes can undergo the gel casting within the VSGE cell, so that nothing else is required;

[0022] (h) other two kind cassettes can form an infinite cassette/UBC complex, which is ideal for the 2-D electrophoresis running;

[0023] (i) improved rubber sealing gasket has an 8-shaped cross section, so as to have much higher compressibility and elasticity, to be compatible with thickness different cassettes;

[0024] (j) an improved heat-absorbing device does not need exogenous coolant, so that is very convenient to use; and

[0025] (k) four disclosed convenient methods can snugly encase almost all kind VSGC cassettes into membrane pouches for both homogeneous and the gradient gel casting without leakage.

BRIEF DESCRIPTION OF THE DRAWINGS

[0026]FIG. 1 is a perspective view of the improved VSGE cell 1.

[0027]FIG. 2 is an exploded perspective view showing the structure of the improved VSGE cell 2.

[0028]FIG. 3 is a set of perspective view illustrating the structure of the improved VSGE cell 3.

[0029]FIG. 4 is an exploded perspective view showing the structure of the improved VSGE cell 4.

[0030]FIG. 5 is a set of perspective view illustrating the structure of the improved VSGE cell 5.

[0031]FIG. 6 is a set of exploded perspective view showing the structure of the improved VSGC cassettes 6-A, 6-B and 6-B.

[0032]FIG. 7 is a set of fragmentary perspective view showing the structure of the improved VSGC cassette 7-A and 7-B.

[0033]FIG. 8 is a set of front view showing the position relationship of the U-shaped rubber sealing-gasket versus the cassette 7-A or 7-B during gel casting or electrophoresis running respectively.

[0034]FIG. 9 is an exploded fragmentary perspective view showing the structure of the improved VSGC cassettes 9.

[0035]FIG. 10 is an exploded perspective view of the improved VSGC cassette 10.

[0036]FIG. 11 is an exploded perspective view of the improved VSGC cassette 11.

[0037]FIG. 12 is an exploded fragmentary perspective view showing a way to modify an ordinary UBC as well as an ordinary U-shaped rubber sealing-gasket, so as to enable the cassette 7-A or 7-B to undergo the gel casting in situ exactly at their electrophoresis running position.

[0038]FIG. 13 is a perspective view of a segment of the infinite cassette/UBC complex 13.

[0039]FIG. 14 is a set of front view showing a method for snugly encasing the VSGC cassettes into a lower softening point plastic membrane pouch for gel casting.

[0040]FIG. 15 is a set of front view showing a method for snugly encasing the VSGC cassettes into an elastic membrane pouch for gel casting.

[0041]FIG. 16 is a set of perspective view showing a method for snugly encasing two VSGC cassettes into an ordinary plastic membrane pouch for gel casting.

[0042]FIG. 17 is a set of perspective view showing a method for snugly encasing the VSGC cassettes into an ordinary plastic membrane pouch for gel casting.

[0043]FIG. 18 is a set of front view showing the structure of the membrane pouch 18-A and 18-B.

[0044]FIG. 19 is a perspective view of the splint pair 19 employed for gel casting.

[0045]FIG. 20 is a perspective view illustrating the method of sandwich those pouch snugly encased cassettes between the splint pair 19 for gel casting.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0046]FIG. 1 is a perspective view of the improved VSGE cell 1. Wherein UBC 22 a has a flat cooling-chamber 24, which divides the UBC 22 a into two compartments, each of them has an upper electrode 26 and a U-shaped side opening with a U-shaped groove 28 alongside it for a rubber sealing-gasket 30 to inlay in. Ceramic sheets 32 a and 32 b are the sidewalls, which are glued on the grids and the frame of the cooling-chamber 24. Banana plug 34 a is for the upper electrode 26 a, while 34 b is for the lower electrode 62, which is hanged under the UBC 22 a. One rubber sealing-gasket 30 b has been pulled out off the U-shaped groove 28 b in this drawing. In many embodiments of the present invention, the employed rubber sealing-gasket is formed by a rubber tubule that has an 8-shaped cross section as the 30 b shown on the bottom of FIG. 1. This way formed rubber sealing-gasket has more elasticity and compressibility, so as to enable admit thickness different cassettes. The UBC 22 a is affixed on the chassis 38 a, which has two lines of mortise 44 s for the foot tenons 42 s of the swing-frame 40 to insert in. Due to all the mortises 44 s are loose mortises, so as to make the swing-frame 40 a and 40 b being swing-able, reversible and demountable. A predetermined gap is left therebetween of each swing-frame 40 and the U-shaped side opening it facing to. Swing-open a swing-frame 40 allows a cassette 50 to lower into the predetermined gap; swing-close the swing-frame can urge the cassette to abut to the UBC 22 a tightly, hence the cassette/UBC complex is formed. Hasp 48 is a favorite holding means for holding the swing-frame 40 in the swing-closed state. As long as the formed complex (regardless one or two cassettes are assembled in) sets into a LBC 52, thereupon the improved VSGE cell 1 is accomplished. Besieges, there is a U-shaped boss 46 sticking out from one face of each swing-frame 40, so as to makes the swing frame 40 a and 40 b being asymmetric from face to face. To reverse the swing-frame 40 a and/or 40 b inside face out can change the width of the gaps, so as to have some compatibility to those thickness different cassettes. Due to the cooling-chamber 24 divides the UBC 22 a into two compartments, both the two upper electrodes 26 are positioned rather high in the UBC, and the employed LBC is shallow; therefore it allows unnecessary to block up the other side opening of the UBC when only a single gel runs in this kind dual gel cell. In FIG. 1, cassette 50 a has been urged tightly abutting to the UBC 22 a by the swing-frame 40 a, while swing-frame 40 b is shown in a demounted state.

[0047]FIG. 2 is an exploded perspective view illustrating the structure of the improved VSGE cell 2. Drawing 2-A shows the structure of UBC 22 b, 34 d is the banana plug for the lower electrode, 28 c and 28 d are two U-shaped groove for the rubber sealing-gaskets 30 to inlay in. Drawing 2-B shows the structure of the swing-frame-pair, which is formed by two swing-frames 40 c and 40 d, a chassis 38 b and a hasp 48 c. Wherein everything is articulated to each other, so that the whole swing-frame pair 2-B is evert-able, and every part wherein is swing-able. After lowering the UBC 2A along with two cassettes into the swing-frame-pair 2-B, swing-close it, and holding it in the swing-closed state by the hasp 48 c, thereupon a cassette/UBC complex is formed. As long as the formed complex seats into a LBC 52, and the heat adsorbing block 5-C (referring to FIG. 5) lowers into the UBC 2-A, thereupon the improved VSGE cell 2 is accomplished. The swing-frame-pair 2-B is avert-able, that mines the span between the swing-frame 40 c and 40 d is adjustable, and this embodiment has some compatibility to those thickness different cassettes. That is because of the hubs are located biased, not located right on, the central line of the thickness of the swing-frame 40 c and/or 40 d. The swing-frame urging-mechanism disclosed in this and the above embodiments is novel, simple, flexible, easy to operate, and very compact. Therefore it allows using much smaller LBC, so as to reduce the pH buffer solution-using amount.

[0048]FIG. 3 is a set of perspective view illustrating the structure of the improved VSGE cell 3. In FIG. 3-A, UBC 22 c has a septum-wall 54 a, 30 e and 30 f are two rubber sealing-gaskets formed by the 8-sectioned rubber tubule as 30 b, 50 b is a cassette that has been urged tightly abutting to the UBC by the cylinder-beam 58 b. The urging mechanism employed in this and the next embodiments is a trapezoidal-apron/cylinder-beam urging mechanism. Its principle is that by arranging a UBC along with two cassettes into a trapezoidal-apron, hence a V-shaped gap is formed therebetween when the apron is a right-angle trapezoidal-apron having one oblique sidewall; but two opposite V-shaped gaps are formed therebetween when the apron is a regular trapezoidal-apron having two oblique sidewalls. In the later case, affix the apron on the other two sides of the UBC. Thereafter, pushing a cylinder-beam into a V-shaped gap can urge the cassette(s) and the UBC to abut to each other tightly. Since the trapezoidal-apron is always affixed on some object, therefore it is better to split it into two trapezoidal half-aprons, as the 56 a and 56 b. So do can offer a great convenience to the operation, but without changing the function of the trapezoidal-apron. In FIG. 3-A, the two trapezoidal half-aprons 56 a and 56 b are formed by splitting a regular trapezoidal-apron into two pieces, and they are affixed aside the UBC 22 c; the cylinder-beam 58 b has been pushed into the V-shaped gap 60 b, the cassette 50 b has been urged to abut to the UBC 22 c tightly. However, since usually a cassette itself is neither rigid nor strong enough, therefore it is better to interpose a rigidity frame 40 e between the cassette 50 and the cylinder-beam 58 before it has been pushed into a V-gape, as shown in FIG. 3-B. Wherein 26 is the wire of the upper electrode, 62 is the wire of the lower electrode. Regardless two or one cassette is assembled in, the cassette/UBC complex is formed. As long as the formed complex sets into a LBC 52, thereupon the improved VSGE cell 3 is accomplished. To replace diameter different cylinder-beams can make the VSGE cell 3 being compatible with thickness different cassettes. By the same reason as mentioned above, it is unnecessary to block up the other side opening of the UBC, when there is only a single gel running in this dual gel cell 3.

[0049]FIG. 4 is a set of perspective view illustrating the structure of improved VSGE cell 4. Wherein 4-A shows the structure of the UBC 22 d and the rigidity frame 40 f If overlooking the cylinder beam 58 c, essentially 4-B is a right angle trapezoidal-apron, but has a wide vertical cut-off made on its oblique wall, so that two trapezoidal half-apron 56 c and 56 d are formed. The rigidity frame 40 g forms the vertical sidewall of the apron 4-B, and 38 b is the chassis. The method of using this embodiment is to hold the UBC 22 d along with two cassettes plus the rigidity frame 40 f in two hands of the operator, and lower them into the right-angle trapezoidal-apron 4-B, and then pushing the cylinder-beam 58 d downward into the V-shaped gap 60 c, thereupon a water-tightly abutted cassette/UBC complex is formed. After seating the formed complex into a LBC 52, and lowering the heat-adsorbing block 5-C (referring to FIG. 5) into the UBC 22 d, thereupon the improved VSGE cell 4 is accomplished. This embodiment has the same advantage as that of the VSGE cell 3, but additionally has a heat-absorbing device.

[0050]FIG. 5 is a set of perspective view illustrating the structures of the improved VSGE cell 5 and 5′. In FIG. 5-A, 22 e is a UBC, 54 b is its septum-wall, 64 a and 64 b are two side holding-arms, which are affixed aside the UBC for holding the cam-beams 66 a and 66 b aside the two U-shaped side openings respectively, but appropriate gaps are left therebetween. Cassette 50 d and rigidity-frame 40 i have been placed at their working positions, urged to tightly abut to the UBC 22 e, so that the cassette/UBC complex is formed. As long as the formed complex seats into a LBC 52, thereupon the improved VSGE cell 5 is accomplished. As shown in this drawing, the cam-beams 66 a and 66 b both are demountable and replaceable, the 66 a is in a demounting and turn-open state, but 66 b is in its working position and is turned-close, each 65 is a lever for turning the cam-beam open or close. There are two ways to make this embodiment to compatible with thickness different cassettes. One way is to replace ellipticity different cam-beams; the other way is to use thumbscrews to urge the cassettes. Therefor eight screw holes 67 s have been equipped on the four end-pieces of the two side holding-arms 67 a and 67 b in order to use the thumbscrews (not showing in this drawing). FIG. 5-B shows another embodiment of the came-beam urging mechanism. Wherein, 38 c is a chassis, 66 c is a cam-beam (it is demountable and replaceable), which is held in its working position by two side holding-arms 64 c and 64 d, whereof the other ends are joined to a vertical rigidity frame 40 h, so that the C-plus-I shaped structure 5-B is formed (by viewing from above) for accommodating the UBC and the cassettes. After lowering the UBC 22 d (referring to FIG. 4-A) along with two cassettes plus the rigidity frame 40 f into this C-plus-I shaped structure 5-B, and then turn-close the cam-beam 66 c, thereupon another cassette/UBC complex is formed. As long as the formed complex sets into a LBC 52, and the heat-absorbing block 5-C lowers into the UBC 22 d, thereupon the improved VSGE cell 5′ is accomplished. FIG. 5-C shows the structure of the heat-adsorbing block 70, wherein 68 is a mass of gel ice (its alternative name is cellulose gum, its chemical composition is sodium methyl cellulose or some analogous) or a block of metal, 69 is an electric insulating crust, 71 is a groove for the upper electrode wire to inlay in, 34 c is a banana plug. This heat-adsorbing block 70 should be kept in a freezer or any cooled enough place before using, and then be lowered into a UBC for absorbing the Joule-heat during electrophoresis. Additionally, block 70 can significantly reduce the using amount of the upper pH buffer solution, as well as allow the upper electrode 26 to mount thereon. Besides, heat-adsorbing block 70 also can be utilized in other kind electrophoresis cells, such as the so-called blotting cells, due to essential they are also gel electrophoresis cells, and wherein the gel slabs are vertically orientated.

[0051]FIG. 6 is a set of exploded perspective view illustrating the structures of the improved VSGC cassettes 6-A, 6-B and 6-C respectively. In cassette 6-A, 72 a is a larger sidewall, 72 b is a smaller sidewall, 74 a and 74 a′ are a pair of flanged spacer strip; each of them has a flat spacer strip part with a flanged strip part aside it; the two flat spacer strip parts are clamped between the respective left and right margins of the two sidewalls 72 a and 72 a′ so as to define a cavity between the four elements for the gel matrix to be cast in; while the two flanged strip parts rest on the respective left and right edges of the smaller sidewall 72 b, so as to form a U-notched upper opening with even rim for the cassette (due to the flanged strip parts have the same thickness as the smaller sidewall), whereby enables the cassette 6-A to achieve a leak-free abutting to the UBC. Cassette 6-B is essentially same to the cassette 6-A, but herein the two flanged spacer strips 74 b and 74 b′ are glued on the larger sidewall 72 c, thus cassette 6-B is a two-element cassette; it still can have two glass and/or ceramics sidewalls. The spacer strips 74 b and 74 b′ both can be formed by the extruded plastic strips, so as to reduce the coat. Polar plastic, such as PVC is a good material for making various spacer strips of the present invention, due to the gel matrix can adhere better to the polar plastic material. When a spacer strip is made of some kind flexible PVC, it can adhere on the sidewalls by itself, so as to offer great convenience for the cassette assembling, referring to the report (2); but hard PVC strips can be glued firmer on the sidewall. Sins the flanged spacer strips 74 b and 74 b′ are glued on the larger sidewall 72 c of cassette 6-B, therefore both of them also can be made of glass. The method is that first glues a narrower glass strip (as thick as the small sidewall 72 d) onto a wider glass strip (its thickness defines the thickness if the gel casting cavity) to form a flanged spacer strip as the 74 b, and then glues it on the larger sidewall 72 c. Or quite the contrary, first glues a wider glass strip on the larger sidewall 72 c, then glues a narrower glass strip atop the wider one to form the flanged spacer strip as the 74 b. In cassette 6-C, the two flanged spacer strips 74 c and 74 c′ are fused with the larger sidewall 72 e. Since usually plastic spacer strips cannot to fuse with a glass sidewall, therefore when we say some spacer strips are fused with a sidewall in this document, it means that both of them are integrated formed either by molded injecting plastic, or by die pressing glass (as making a glass ashtray). In addition, when we say some spacer strips are affixed on a sidewall, it means that the spacer strips can either be glued on the sidewall, or are fused with the sidewall. Cassette 6-C is also a two-element cassette, wherein the flanged spacer strip 74 c and 74 c′ are integrated formed with the larger sidewall 72 e. Since it must be molding formed, therefore it allows some small modification to be made on the mold without increasing the cost. Actually, the four 45 degree transition angles are made at the upper and lower end positions of the two flanged spacer strips 74 c and 74 c′, as showing in FIG. 6-C. And correspondingly, the four corners of the smaller sidewall 72 f have been ground off The advantage of doing such a small modification is due to it can restrain the smaller sidewall 72 f from sliding to any direction. Regardless the larger sidewall is plastic or glass, the smaller sidewalls in cassette 6-A, 6-B or 6-C still can be ceramic or glass, since they are the inner sidewalls, facing to the UBC, unnecessary to be transparent.

[0052]FIG. 7 is a set of fragmentary perspective view illustrating the structures of the improved VSGC cassettes 7-A and 7-B. In cassette 7-A, the U-shape flanged spacer 76 is formed by linking the two flanged spacer strips 74 a and 74 a′ (as in cassette 6-A or 6-B) to each other by a flanged spacer strip beam adjoined therebetween at their two lower ends. Therefore a U-shaped flanged spacer is formed, which has two upward sidearm and a bottom horizontal beam. The flat spacer part of the horizontal beam portion has degenerated into one shark tooth 78 for clipping between the lower margins of the two sidewalls 72 g and 72 h, so as to increase the compression strength of the bottom margin area (the mastoid 84 of cassettes 7-B and the mastoids in the two-element cassettes, as in cassette 9, cassettel 1, cassettes 6-B and 6-C, all have the same function as the shark tooth 78); while the flanged part of the horizontal beam portion has narrowed down approximately 1 to 2 mm from its top edge, but except the very left and very right two tab areas, which rest on the respective very left and very right ends of the bottom edge of the smaller side wall 72 h. As a result, the lower opening 80 has been diverted from usually downward direction into the abutting face direction of the cassette 7-A or cassette 7-B. This U-shaped flanged spacer 76 is glued on the larger sidewall 72 g in cassette 7-A, but the U-shaped flanged spacer 76′ is fused with the larger sidewall 72 g′ in cassette 7-B. Thereafter, the only two remaining assembling seams 82, 82′ and the lower opening 80 are all located on the abutting face of cassette 7-A or cassette 7-B. This characteristic of cassette 7-A and 7-B is valuable, but only if it is aware. The value is the assembling seams 82, 82′ and the lower opening 80 of cassette 7-A and 7-B can be sealed up simultaneously by resting a U-shaped rubber sealing gasket on them for gel casting.

[0053]FIG. 8 is a set of front view showing the position relationship of the U-shaped rubber sealing-gasket versus the cassette 7-A or 7-B during gel casting or electrophoresis running respectively. Wherein 8-A shows that the U-shaped rubber sealing-gasket 30 ought to rest on the two vertical assembling seams 82 and 82′ as well as on the lower opening 80 of the cassette 7-A or 7-B during performing the gel casting. However, when the U-shaped rubber-sealing gasket 30 is a part of a VSGE cell, it means that the cassettes 7-A and 7-B can undergo the gel casting within the VSGE cell, and subsequently to carry out the electrophoresis just by shifting the cassette downward for a little distance, as shown in FIG. 8-B. It is worth to point out that although there are two vertical assembling seams 82 and 82′ on the abutting faces of cassette 7-A or 7-B, but no upper pH buffer solution can leak out by either along or across them during electrophoresis running. That is because of the assembling seam 82 and 82′ are also filled with gel matrix, after the gel matrix to be cast into the cassette by using our gel casting method; besides, the rubber sealing-gasket 30 always rests on the assembling seam 82 and 82′ during electrophoresis running. This situation is also true to all the cassettes 6-A, 6-B, and 6-C as well as to the cassette 10 and cassette 11.

[0054]FIG. 9 is an exploded perspective view of the improved VSGC cassette 9. Wherein 72 i is a longer sidewall, 72 j is a shorter sidewall, 74 d and 74 d′ are two flanged spacer strips; each of them has a flat spacer strip part with a flanged tab part atop it, Thereof the two flat spacer strip parts are clipped between the respective left and right margins of the two sidewalls 72 i and 72 j, while the two atop flanged tab parts rest atop the respective left and right ends of the top edge of the shorter sidewall 72 j. The flanged spacer strips 74 d and 74 d′ are glued on, or fused with, the shorter sidewall 72 j, but leaving the longer sidewall 72 i demountable. Cassette 9 still can have two glass and/or ceramic sidewalls if the spacer strips are glued on the shorter wall. Each of the flanged spacer strips 74 d and 74 d′ can be an integrated one piece as showing in the drawing, but also can be formed by a flat spacer strip of plastic or glass with a square tab of plastic or glass to be glued on it, as the 74 d″.

[0055]FIG. 10 is an exploded perspective view of the improved VSGC cassette 10. Wherein 72 k and 72 k′ are two identical sidewalls, 74 e and 74 e′ are a pair of flanged spacer strips; each of them has a T-shaped cross section. Whereof the two flat spacer strip parts are clamped between the respective left and right margins of the two identical sidewalls 72 k and 72 k′, while the two T-head parts rest on the respective left and right side edges of the two identical side walls, then a U-notched upper opening is formed simply due to the spacer strips are longer than the sidewalls. Herein the formed U-notched upper opening exposes to the two opposite face directions of cassette 10. The two spacer strips 74 e and 74 e′ are allowed to affix on any one of the two sidewalls. Besides, both of the upper inner angles of the glass sidewalls 72 k and 72 k′ are ground off, so as to form a V-shaped beak 86 within the U-notched upper opening of this kind cassette.

[0056]FIG. 11 is an exploded perspective view of the improved VSGC cassette 11. Wherein 72 m is a narrower sidewall, 72 n is a wider sidewall, 74 f and 74 f′ are a pair of flanged spacer strip; each of them has a flat spacer strip part with a flanged tab part atop it on one face, while with a flanged strip part aside it on the other face. Whereof the two flat spacer strip parts are clamped between the respective left and right margins of the two side walls 72 m and 72 n, the two atop flanged tab parts rest on the respective left and right ends of the top edge of the wider sidewall 72 n, while the two aside flanged strip parts rest on the respective left and right edges of the narrower sidewall 72 m. The two spacer strips 74 f and 74 f′ are affixed on the wider sidewall 72 n, but leaves the narrower sidewall 72 m being demountable. This cassette also can have the V-shaped beak 86 as the cassette 10, and still can have two glass and/or ceramic sidewalls when the two spacer strips are glued on the wider sidewall. Cassette 10 and 11 are ideal for the 2^(nd)-D electrophoresis running of the 2-D gel electrophoreses method. Because, each of these cassettes has two abutting faces, whereby can form an infinite cassette/UBC complex by alternately abutting with appropriate UBC modules. In addition, the V-shaped beak 86 provided an advantage that allows using a much thicker gel cylinder to run the 1^(st)-D isoelectric focusing of the 2-D gel electrophoreses, so as to significantly enhance the sensitivity of the 2-D gel electrophoresis analysis method.

[0057]FIG. 12 is an exploded fragmentary perspective view diagramming a way to modify a regular UBC as well as a regular rubber sealing-gasket in order to make the cassettes 7-A or 7-B can undergo the gel casting in situ exactly at their electrophoresis running position. Wherein the modification includes that; on one hand, makes each U-shaped side opening of an ordinary UBC to have a downward, coplanar and penetrable lip 88, by such as punching a row of small hole 90 thereon; on the other hand, splits the horizontal beam part of a regular U-shaped rubber sealing gasket into two strands, so as to form a horizontal loop 92 at the bottom of the modified U-shaped rubber sealing gasket 30′. After inlaying the modified rubber sealing gasket 30′ into the modified U-shaped groove 28′, the lower horizontal loop 92 just loops around the row of small hole 90. However, for showing all things clearly in a single drawing, the modified rubber sealing gasket 30′ has been pulled out off the modified U-shaped groove 28′, as shown in FIG. 12. The way to use this embodiment is that firstly to adhere a strip of water dipped semipermeable membrane 94 aside the horizontal loop 92, and then to force the cassette 7-A or 7-B to rest on the modified UBC 22 e by aiming the lower opening 80 of the cassette at the row of small hole 90. As a result, the semipermeable membrane 94 is tightly clamped therebetween, functionally to seal up the lower opening 80 of the cassette 7-B or 7-A. This embodiment enables the cassettes 7A or 7-B to undergo the gel casting in situ exactly at theirs electrophoresis running position, and subsequently to carry out the electrophoresis without need to move or remove anything. Although 30 years ago in U.S. Pat. No. 3,419,580, a semipermeable membrane had been employed to seal up the lower opening of the gel-casting cavity of the VSGE cell. However, there was no independent gel-casting cassette in that VSGE cell, and wherein the semipermeable membrane was a build-in part of the VSGE cell, so it was not easy to be replaced from time to time.

[0058]FIG. 13 is a perspective view of a segment of the infinite cassette/UBC complex 13. Wherein each 11 is a cassette 11 or a cassette 10, each 22 m is a UBC module, each 86 is a V-shaped beak of the cassette, and each 96 symbolizes a clamping means. This drawing shows that by abutting the cassette 10 or 11 alternately with the UBCm modular can form an infinite cassette/UBC complex. This complex 13 can be extended as long as required, and stooped at any length by clamping two plastic plats at the two ends respectively. This embodiment can guarantee a numerous vertical slab gels to carry out the electrophoresis parallel in it under an identical condition. Therefore it is ideal for multiple the 2nd-D electrophoresis running of the 2-D gel electrophoreses simultaneously.

[0059]FIG. 14 is a set of front view showing a method for snugly encasing the VSGC cassettes into a plastic membrane pouch for gel casting. The method is that firstly to place one or several pieces of face-to-face arranged cassettes 50 into a roomy plastic membrane pouch 100 a, which has a lower softening point; then using some means to hold the open mouth area of the pouch, so as to prevent the mouth area from over shrinking; and then using a hot air blower to blow the plastic pouch 100 a causing it shrinking. Thereafter the pouch 100 a snugly wraps around the cassettes 50. After removing the holding means, the cassettes 50 are ready to be sandwiched between two splints for gel casting. This method is good for encasing any sized VSGC cassettes for gel casting. FIG. 14-A shows that a wide camp 96 w is employed to hold the open mouth. FIG. 14-B shows that by partially fusing the open mouth area, such as the 98 labeled area, and then to cut it off after shrinking.

[0060]FIG. 15 is a set of front view showing a method for snugly encasing the VSGC cassettes into an elastic membrane pouch for gel casting. Wherein 50 is one or several pieces of face-to-face arranged cassettes, but are placed upside-down; 100 b is an elastic membrane pouch that has a tail tubule 110 a at the bottom, and its cuff area has been curled up, so that a thicken beaded cuff 102 is formed; 104 and 104′ are two fingers, or any kind of stretching means, for propping up the elastic pouch 100 b until it is expanded wide enough. Then wraps the expanded elastic pouch 100 b around the cassettes 50, as showing in FIG. 15-A. After removing the stretching means, releasing the beaded cuff 102 as showing in FIG. 15-B, and turning the cassettes right side up, thereupon the cassettes 50 are ready for the next step of gel casting. For the gradient gel casting, the gel forming solution should be injected into the pouch 100 b via its tail tubule 110 a (referring to FIG. 18). For regular uniform gel casting, the elastic membrane pouch needs not to have the tail tubule 110 a.

[0061]FIG. 16 is a set of perspective view showing a method for snugly encasing two VSGC cassettes into an ordinary plastic membrane pouch for gel casting. In FIG. 16-A, two cassette 50 and 50′ have been placed into a size appropriate ordinary plastic membrane pouch 100 c. FIG. 16-B shows that the cassette 50 and 50′ have been arranged to be side-by-side. FIG. 16-C and 16-D shows that a propping means, such as a plastic stick 106 a or a plastic card 108 a, has already rested on the central line of the pouch 100 c. While FIG. 16-E and 16-F show that by using the propping means as an inflection point to fold up the plastic pouch 100 c until the cassette 50 and 50′ from side-by-side became face-to-face. Thereafter, the cassette 50 and 50′ are snugly incased in the pouch 100 c, and ready for the next step of gel casting. FIG. 16 disclosed a very convenient method to snugly encase two cassettes at once for gel casting. General specking, placing n piece cassettes (n>1) side-by-side into an appropriate membrane pouch, then using n−1 pieces propping means from outside to rest on the pouch at the positions between each two neighboring cassettes, then by using the propping means as the inflection points to zigzag fold up the membrane pouch until all the cassettes from side-by-side became face-to-face, thereupon those cassettes are ready for the next step of gel casting.

[0062]FIG. 17 is a set of perspective view showing a method for snugly encasing the VSGC cassettes into an ordinary plastic membrane pouch for gel casting. Wherein 17-A shows that one or several pieces of face to face arranged cassettes 50 have been placed into a roomy plastic membrane pouch 100 d, and have been moved to one side of the pouch. A propping means, such as the plastic stick 106 b, or the bent edge of the plastic card 108 b, is employed to rest on the pouch 100 d at the position as close as to the cassettes. Then the method is using the propping means as a point of inflection to fold the remainder of the pouch 100 d towards the cassette side, and to hold it in such a folding state by such as a piece of adhesive tape 112, as shown in FIG. 17-B. Thereafter the cassettes 50 are snugly incased in the pouch 100 d, and ready for the next step of gel casting. This method is very convenient and flexible. Besides, it also can be used to cast the gradient gels, provided the employed plastic membrane pouch has a tail tubule at the bottom (referring to FIG. 18).

[0063]FIG. 18 is a set of front view showing the structure of the membrane pouches, each of them has a tail tubule. FIG. 18-A shows the structure of the elastic membrane pouch 100 b, 110 a is its tail tubule. FIG. 18-B shows the structure of the inelastic membrane pouch 100 d′, 110 d′ is its tail tubule.

[0064]FIG. 19 is a perspective view of the splint pair 19 employed for gel casting. Wherein 114′ is a movable splint, 114 is a immovable splint that has a base plate 116 attached under it, 118 is a V-shaped cut off formed on the base pleat 116 for the tail tubule 110 to pass through, 120 is a bottom stand for raising up the splint pair 114 and 114′ atop it, so as to perform the gradient gel casting; and each 96 symbolizes a clamping means.

[0065]FIG. 20 is a perspective view showing the way to sandwich the VSGC cassettes between the splint pair 19 for gel casting. Wherein 50 are the cassettes that have been snugly incased in a membrane pouch; 114 and 114′ is a splint pair, each 96 symbolizes a clamping means. For performing regular uniform gel casting, the gel forming solution can be poured into the cassettes from their upper openings. For performing the gradient gel casting, the splint pair 114 and 114′ should be raised atop the bottom stand 120, as showing in FIG. 19, the employed pouch should have a tail tubule 110 at the bottom (referring to FIG. 18), and the gel forming solution should be injected into the pouch via its tail tubule 110.

[0066] After review the specification and the drawings, it is obvious that almost all aspects, but the structural style, about the VSGE cells and related methods have been improved in the present innovations. So the present innovated VSGE cells are still belong to the most popular styled VSGE cells, as mentioned in the background paragraph. Since the most popular styled VSGE cells are very familiar to every manufacturer as well as to every laboratory technician, so that there is no necessary to point out which face of the cassette is the abutting face that should to be used to abut to the UBC, where of a UBC the cassette should to be abutted at, etc. In addition, when we say two cassettes abut to a UBC, it means that the cassettes are forced to rest on the two U-shaped rubber sealing-gaskets of the UBC respectively, or means that the two cassettes are forced to sandwich a UBC between them.

REFERENCES

[0067] (1) Madjar, Jean-Jacques, Monique Arpin and Jean-Paul Reboud

[0068] A Simple Water-Cooled Apparatus for Two-Dimensional Gel Electrophoresis Analytical Biochemistry. 83: 304-310 (1977)

[0069] (2) Tichy, Herbert

[0070] A Multisample Electrophoresis Apparatus Using Vertical Polyacrylamide Gel Slabs Analytical Biochemistry 17: 320-326. (1966)

[0071] (3) Studier, F. William

[0072] Analysis of Bacteriophage T7 Early RNAs and Proteins on Slab Gels Journal of Molecular Biology 79: 237-248 (1973)

[0073] (4) Tech Note 5018-A (1996), of Bio-Rad Laboratories, Inc.

[0074] 2000 Alfread Nobel Drive, Hercules, Calif. 94547, USA

[0075] (5) Margolis, J. and K. G. Kenrick

[0076] Polyacrylamide Gel Electrophoresis in a Continuous Molecular Sieve Gradient Analytical Biochemistry 25: 347-362 (1968).

[0077] (6) Ornstein, Leonard

[0078] Disc Electrophoresis-I Background And Theory Annals New York Academy of Sciences 121: 321-329. (1964)

REFERENCE NUMERALS IN DRAWINGS

[0079]22 UBC 24 cooling-chamber

[0080]26 upper electrode 28 U-shaped groove

[0081]30 rubber sealing-gasket 32 ceramic sheet

[0082]34 banana plug 36 inlet/outlet

[0083]38 chassis 40 rigidity frame

[0084]42 tenon 44 loose mortise

[0085]46 U-shaped boss 48 hasp

[0086]50 VSGC cassette 52 LBC

[0087]54 septum-wall 56 trapezoidal half-apron

[0088]58 cylinder-beam 60 V-shaped gap

[0089]62 lower electrode 64 side holding-arm

[0090]65 lever 66 cam-beam

[0091]67 screw hole 68 gel-ice or metal block

[0092]69 electric insulating crust 70 heat-absorbing block

[0093]71 groove for electrode wire 72 cassette wall

[0094]74 flanged spacer strip 76 U-shape flanged spacer

[0095]78 shark tooth 80 lower opening

[0096]82 assembling-seam 84 mastoid

[0097]86 V-shaped beak 88 downward lip

[0098]90 penetrated holes 92 horizontal loop

[0099]94 semipermeable membrane 96 clamping means

[0100]98 fused area 100 membrane pouch

[0101]102 beaded cuff 104 finger

[0102]106 plastic stick 108 plastic card

[0103]110 tail tubule 112 adhesive tape

[0104]114 splint 116 base plate

[0105]118 V-shaped cut off 120 bottom stand 

What is claimed is:
 1. An improved vertical slab gel electrophoresis cell and method for performing electrophoresis vertically within uprightly oriented slab shaped gel matrixes comprising: (i) an upper buffer chamber for rooming an upper pH buffer solution and an upper electrode, having base plate, sidewalls and two opposite U-shaped side openings, each of them has a U-shaped rubber sealing-gasket attached alongside it, so as to allow a vertical slab gel casting cassette to abut thereat; (ii) said vertical slab gel casting cassette is a vertical flat cavity for said gel matrix to be cast therein, and said electrophoresis to take place therein, having two opposite main sidewalls, closed left and right edges, a lower opening and a U-notched upper opening; (iii) an urging mechanism for urging said cassettes and said upper buffer chamber to water-tightly abut to each other, so as to form a cassette/upper buffer chamber complex with said U-notched upper openings exposing into it; (iv) a lower buffer chamber having base plate and side walls for rooming a lower pH buffer solution, a lower electrode, and said cassette/upper buffer chamber complex therein; (v) a nonessential heat absorbing device for absorbing the Joule-heat during electrophoreses running upon requirement; and (vi) some step and method for insuring said gel matrix to be cast into said vertical slab gel casting cassettes without leakage; wherein the improvement including: (a) using a hallow lower buffer chamber; (b) planting an object, such as a septum-wall or a cooling-chamber, into said upper buffer chamber to divide said upper buffer chamber into two compartments making each of them having a U-shaped side opening; (c) positioning said upper electrodes in said compartments at such an altitudes, so that they are beyond the upper edges of the sidewalls of said lower buffer chamber after said upper buffer chamber sets into said lower buffer chamber; whereby the three points cooperated together allows unnecessary to block up the other side opening when a single gel runs in such a dual gel electrophoresis cell, but it still can guarantee two gels to parallel run the electrophoresis in it under an identical conditions.
 2. An improved vertical slab gel electrophoresis cell and method for performing electrophoresis vertically within uprightly oriented slab shaped gel matrixes comprising: (i) an upper buffer chamber for rooming an upper pH buffer solution and an upper electrode, having base plate, sidewalls and two opposite U-shaped side openings, each of them has a U-shaped rubber sealing-gasket attached alongside it, so as to allow a vertical slab gel casting cassette to abut thereat; (ii) said vertical slab gel casting cassette is a vertical flat cavity for said gel matrix to be cast therein, and said electrophoresis to take place therein, having two opposite main sidewalls, closed left and right edges, a lower opening and a U-notched upper opening; (iii) an urging mechanism for urging said cassettes and said upper buffer chamber to water-tightly abut to each other, so as to form a cassette/upper buffer chamber complex with said U-notched upper openings exposing into it; (iv) a lower buffer chamber having base plate and side walls for rooming a lower pH buffer solution, a lower electrode, and said cassette/upper buffer chamber complex therein; (v) a nonessential heat absorbing device for absorbing the Joule-heat during electrophoreses running upon requirement; and (vi) some step and method for insuring said gel matrix to be cast into said vertical slab gel casting cassettes without leakage; wherein the improved urging mechanism comprising: (a) equipping a swing-frame aside each U-shaped side opening of said upper buffer chamber, but an appropriate gap is left therebetween; (b) swing-open said swing-frame(s), lowering said cassette(s) into said gap(s); (c) swing-close said swing-frame(s), and holding said swing-frame(s) in the swing-closed state by a favorite means, hence said cassette(s) and said upper buffer chamber are urged to abut to each other tightly, and said cassette/upper buffer chamber complex is formed; whereby disclosed mechanism is novel, simple, compact, flexible and easy to operate; besides, to evert the swing-frame(s) inner face out can make the electrophoresis cell to be compatible with thickness different cassettes.
 3. An improved vertical slab gel electrophoresis cell and method for performing electrophoresis vertically within uprightly oriented slab shaped gel matrixes comprising: (i) an upper buffer chamber for rooming an upper pH buffer solution and an upper electrode, having base plate, sidewalls and two opposite U-shaped side openings, each of them has a U-shaped rubber sealing-gasket attached alongside it, so as to allow a vertical slab gel casting cassette to abut thereat; (ii) said vertical slab gel casting cassette is a vertical flat cavity for said gel matrix to be cast therein, and said electrophoresis to take place therein, having two opposite main sidewalls, closed left and right edges, a lower opening and a U-notched upper opening; (iii) an urging mechanism for urging said cassettes and said upper buffer chamber to water-tightly abut to each other, so as to form a cassette/upper buffer chamber complex with said U-notched upper openings exposing into it; (iv) a lower buffer chamber having base plate and side walls for rooming a lower pH buffer solution, a lower electrode, and said cassette/upper buffer chamber complex therein; (v) a nonessential heat absorbing device for absorbing the Joule-heat during electrophoreses running upon requirement; and (vi) some step and method for insuring said gel matrix to be cast into said vertical slab gel casting cassettes without leakage; wherein the improved urging mechanism comprising: (a) placing said upper buffer chamber along with two said cassettes into a trapezoidal-apron, so that a V-shaped gap is formed therebetween when said apron is a right-angle trapezoidal-apron having one oblique wall, but two V-shaped gaps are formed therebetween when said apron is a regular trapezoidal-apron having two opposite oblique walls; in the later case, affixing said apron on the two side walls of said upper buffer chamber, so that said apron is around said upper buffer chamber; (b) pushing cylinder-beam(s) downward into said V-shaped gap(s), hence said cylinder-beam(s) urges said cassette(s) and said upper buffer chamber to abut to each other tightly, and said cassette/upper buffer chamber complex is formed; (c) interposing a rigidity-frame between said cassette and said cylinder-beam before it is pushed into said V-shaped gap, provided said cassette itself is neither strong nor rigid enough; (d) said trapezoidal-apron is allowed to be split into two trapezoidal half-aprons when they have chance to affix on a third party; whereby disclosed mechanism is also novel, simple, compact, flexible and easy to operate; besides, to replace diameter different cylinder-beams can make the electrophoresis cell to be compatible with thickness different cassettes.
 4. An improved vertical slab gel electrophoresis cell and method for performing electrophoresis vertically within uprightly oriented slab shaped gel matrixes comprising: (i) an upper buffer chamber for rooming an upper pH buffer solution and an upper electrode, having base plate, sidewalls and two opposite U-shaped side openings, each of them has a U-shaped rubber sealing-gasket attached alongside it, so as to allow a vertical slab gel casting cassette to abut thereat; (ii) said vertical slab gel casting cassette is a vertical flat cavity for said gel matrix to be cast therein, and said electrophoresis to take place therein, having two opposite main sidewalls, closed left and right edges, a lower opening and a U-notched upper opening; (iii) an urging mechanism for urging said cassettes and said upper buffer chamber to water-tightly abut to each other, so as to form a cassette/upper buffer chamber complex with said U-notched upper openings exposing into it; (iv) a lower buffer chamber having base plate and side walls for rooming a lower pH buffer solution, a lower electrode, and said cassette/upper buffer chamber complex therein; (v) a nonessential heat absorbing device for absorbing the Joule-heat during electrophoreses running upon requirement; and (vi) some step and method for insuring said gel matrix to be cast into said vertical slab gel casting cassettes without leakage; wherein the improved urging mechanism comprising: (a) using two side-holding-arms to hold a cam-beam aside a U-shaped side opening of said upper buffer chamber, but an appropriate gap is left therebetween; (b) lowering said cassette into said gap, and then turning close said cam-beam, hence said cassette and said upper buffer chamber are urged to abut to each other tightly, and said cassette/upper buffer chamber complex is formed, due to said urging mechanism can restrain said upper buffer chamber from moving away when said cam-beam is turned close; (c) interposing a rigidity-frame between said cassette and said cam-beam before it is turned close, provided said cassette itself is neither strong nor rigid enough; whereby disclosed urging mechanism has nothing to do with said lower buffer chamber.
 5. The electrophoresis cell and method of claim 4, wherein (a) said two side-holding-arms have four holding ends, which hold two cam-beams aside the two U-shaped side openings of said upper buffer chamber respectively; (b) said two side-holding-arms are affixed on the two sidewalls of said upper buffer chamber, thus said two side-holding-arms can restrain said upper buffer chamber from moving away when any of said cam-beams is turned close.
 6. The electrophoresis cell and method of claim 4, wherein (a) each of said two side holding arms has one cam-beam holding end; (b) said two side holding arms hold a cam-beam therebetween at their holding ends; (c) said two side-holding-arms are linked to each other by a vertical rigidity-frame adjoined therebetween at the ends other than the cam-beam holding ends, so that a C-plus-I shaped structure is formed for accommodating said upper buffer chamber and said cassettes therein; (d) lowering said upper buffer chamber along with two said cassettes into said C-plus-I shaped structure, and then turning said cam-beam close; thus said cam-beam urges the first cassette of said two cassettes toward said upper buffer chamber, but said vertical rigidity-frame and the second cassette restrain said upper buffer chamber from moving away from said first cassette; as a result, said two cassettes sandwich said upper buffer chamber therebetween tightly; thereupon said cassette/upper buffer chamber complex is formed.
 7. An improved vertical slab gel electrophoresis cell and method for performing electrophoresis vertically within uprightly oriented slab shaped gel matrixes comprising: (i) an upper buffer chamber for rooming an upper pH buffer solution and an upper electrode, having base plate, sidewalls and two opposite U-shaped side openings, each of them has a U-shaped rubber sealing-gasket attached alongside it, so as to allow a vertical slab gel casting cassette to abut thereat; (ii) said vertical slab gel casting cassette is a vertical flat cavity for said gel matrix to be cast therein, and said electrophoresis to take place therein, having two opposite main sidewalls, closed left and right edges, a lower opening and a U-notched upper opening; (iii) a urging mechanism for urging said cassettes and said upper buffer chamber to water-tightly abut to each other, so as to form a cassette/upper buffer chamber complex with said U-notched upper openings exposing into it; (iv) a lower buffer chamber having base plate and side walls for rooming a lower pH buffer solution, a lower electrode, and said cassette/upper buffer chamber complex therein; (v) a nonessential heat absorbing device for absorbing the Joule-heat during electrophoreses running upon requirement; and (vi) some step and method for insuring said gel matrix to be cast into said vertical slab gel casting cassettes without leakage; wherein the improved heat-absorbing device is a block of material selected from the group consisting of gel-ice and metals, coated with an electric insulation crust, for storing in a lower temperature place before use and then lowering into said upper buffer chamber in order to absorb the Joule-heat during electrophoreses running; whereby disclosed heat-absorbing device does not need to use exogenous coolant; it can significantly reduce the using amount of the upper pH buffer solution, and allow the upper electrode to mount on; besides, it also can be utilized in the electro-blotting cell, due to essentially it is a kind of electrophoresis cell, and wherein the slab gels are vertically disposed.
 8. An improved vertical slab gel electrophoresis cell and method for performing electrophoresis downward within uprightly oriented slab shaped gel matrixes comprising: (i) an upper buffer chamber for rooming an upper pH buffer solution and an upper electrode, having base plate, sidewalls and two opposite U-shaped side openings, each of them has a U-shaped rubber sealing-gasket attached alongside it, so as to allow a vertical slab gel casting cassette to abut thereat; (ii) said vertical slab gel casting cassette is a vertical flat cavity for said gel matrix to be cast therein, and said electrophoresis to take place therein, having two opposite main sidewalls, closed left and right edges, a lower opening and a U-notched upper opening; (iii) an urging mechanism for urging said cassettes and said upper buffer chamber to water-tightly abut to each other, so as to form a cassette/upper buffer chamber complex with said U-notched upper openings exposing into it; (iv) a lower buffer chamber having base plate and side walls for rooming a lower pH buffer solution, a lower electrode, and said cassette/upper buffer chamber complex therein; (v) a nonessential heat absorbing device for absorbing the Joule-heat during electrophoreses running upon requirement; and (vi) some step and method for insuring said gel matrix to be cast into said vertical slab gel casting cassettes without leakage; wherein the improved vertical slab gel casting cassette comprising: (a) two plates of rectangular sidewall; (b) a pair of flanged spacer strip, each of them has a flat spacer strip part connected with flanged part(s); (c) said flat spacer strip parts are clamped between the respective left and right margins of said two sidewalls, so as to define said cavity therebetween for said gel matrix to cast in; while (d) said flanged parts rest on the edge(s) of said sidewall(s), so as to form said U-notched upper opening with even rim for said cassette; (e) said two spacer strips are allowed to affix on a chosen sidewall, but leaving the other sidewall demountable; whereby disclosed structure without using notched sidewall, but still can form a U-notched upper opening with even rim for the cassette, so as to insure a leak-free abutting of the cassette to the upper buffer chamber, and can reduce the fragility and cost of the cassette.
 9. The electrophoresis cell and method of claim 8, wherein said vertical slab gel casting cassette comprising: (a) a plate of smaller sidewall; (b) a plate of larger sidewall; (c) a pair of flanged spacer-strips, each of them has a flat spacer-strip part with a flanged strip part aside it; (d) said two flat spacer strip parts are clamped between the respective left and right margins of said two sidewalls; while (e) said two flanged strip parts rest on the respective left and right edges of said smaller sidewall; whereby disclosed cassette can have at least one glass or ceramic sidewall.
 10. The electrophoresis cell and method of claim 9 wherein a further improvement including: (a) said pair of flanged spacer strips are linked to each other by a flanged spacer beam adjoined at both of their lower ends, so as to form a U-shaped flanged spacer, which has two upward side arms and a horizontal bottom beam, (b) the flat spacer strip part of said horizontal beam region has degenerated down into a shark tooth for clamping between the lower margins of said two sidewalls, so as to enhance the compressive intensity of the lower margin area; while (c) the flanged strip part of said horizontal beam region has narrowed down approximately 1 to 2 mm from its top edge, but except the very left and very right two tab areas, which rest on the respective very left and very right ends of the bottom edge of said smaller sidewall, as a result the lower opening of said cassette has been deflected from conventionally downward direction into the abutting face direction of this kind cassette; (d) said U-shaped flanged spacer strip is affixed on said larger sidewall, but leaving said smaller sidewall demountable, thereupon a two-element cassette is formed, whose only two remained assembling-seams and said lower opening are all located on the abutting face of said cassette; (e) resting said cassette onto a U-shaped rubber sealing-gasket, letting the two upward side arms of said sealing-gasket to rest on the two assembling-seams of said cassette respectively, while the lower beam of said sealing-gasket to rest on the lower opening of said cassette simultaneously, thereupon the two assembling-seams and the lower opening of said cassette are all sealed up for performing said gel casting without leakage; and subsequently to carry out the electrophoresis just by shifting said cassette downward for a little distance to expose the lower opening of said cassette under the lower beam of said sealing-gasket, but keeping the two upward side arms of said sealing-gasket still to rest on the two assembling-seams of said cassette, provided said U-shaped rubber sealing-gasket is a part of said electrophoresis; whereby disclosed structure and method makes nothing else is required, nothing else need to do for gel casting.
 11. The electrophoresis cell and method of claim 10 wherein the even further improvement comprising: (a) making the U-shaped side opening of an ordinary upper buffer chamber to have a coplanar downward lip, and making said lip being penetrable by such as punching a row of small holes thereon; (b) splitting the horizontal beam region of an ordinary U-shaped rubber sealing-gasket into two branches, hence a horizontal loop is formed at the bottom of the modified U-shaped rubber sealing-gasket; (c) attaching said modified U-shaped rubber sealing-gasket alongside the U-shaped side opening of said modified upper buffer chamber in such a way, so that said horizontal loop part just loops around said row of small holes; (d) pasting a strip of water soaked semipermeable membrane onto the horizontal loop of said modified rubber sealing gasket, and then to urge the cassettes of claim 10 to rest on said modified upper buffer chamber by aiming the lower opening of said cassette at the row of small holes of said modified upper buffer chamber, hence said semipermeable membrane is tightly clamped therebetween, so as to seal up the lower opening of said cassette for gel casting; whereby disclosed improvements enables the cassette of the claim 10 to undergo the gel casting in situ exactly at its electrophoresis running position, and afterward to carry out the electrophoresis without need to move or remove anything; besides, any other kind vertical slab gel casting cassette still can be utilized in this electrophoresis cell, provided it has a U-notched upper opening and is pre-cast with gel matrix.
 12. The electrophoresis cell and method of claim 8 wherein said vertical slab gel casting cassette comprising: (a) a plate of shorter sidewall; (b) a plate of longer sidewall; (c) a pair of flanged spacer strip, each of them has a flat spacer strip part with a flanged tab part atop it; (d) said two flat spacer strip parts are clamped between the respective left and right margins of said two sidewalls; while (e) said two flanged tab parts rest atop the respective left and right ends of the top edge of said shorter sidewall; (f) said two flanged spacer strips are affixed on said shorter sidewall, but leaving said longer sidewall demountable; whereby disclosed cassette is also a two-element cassette, which still can have two glass and/or ceramic side walls, or a glass or ceramic side wall plus a plastic side wall.
 13. The electrophoresis cell and method of claim 8 wherein said vertical slab gel casting cassette comprising: (a) two plates of identical sidewalls; (b) a pair of flanged spacer strips, each of them has a T-shaped cross section; (c) the flat spacer strip parts of said two flanged spacer strips are clamped between the respective left and right margins of said two identical sidewalls; while (d) the T-head parts of said two flanged spacer strips rest on the respective left and right edges of said two identical sidewalls, so that said U-notched upper opening is formed simply due to said two spacer strips are longer than said two sidewalls; (e) said flanged spacer strips are allowed to affix on any of said two sidewalls; whereby disclosed cassette has such a U-notched upper opening, which exposes to the both face directions of the cassette, so as to enable forming an infinite cassette/upper buffer chamber complex.
 14. The electrophoresis cell and method of claim 8 wherein said vertical slab gel casting cassette comprising: (a) a plate of narrower sidewall; (b) a plate of wider sidewall; (c) a pair of flanged spacer strips, each of them has a flat spacer strip part with a flanged tab part atop it on one face, while with a flanged strip part aside it on the other face; (d) said two flat spacer strip parts are clamped between the respective left and right margins of said two sidewalls; (e) said two atop flanged tab parts rest atop the respective left and right ends of the top edge of said wider sidewall, while said two aside flanged strip parts rest on the respective left and right edges of said narrower sidewall; (f) said two flanged spacer strips are affixed on said wider sidewall, but leaving said narrower sidewall demountable; whereby disclosed cassette has the same function as the cassette of the claim 13, but this one is a two-element cassette, is easer to manipulate.
 15. An improved vertical slab gel electrophoresis cell and method for performing electrophoresis vertically within uprightly oriented slab shaped gel matrixes comprising: (i) an upper buffer chamber for rooming an upper pH buffer solution and an upper electrode, having base plate, sidewalls and two opposite U-shaped side openings, each of them has a U-shaped rubber sealing-gasket attached alongside it, so as to allow a vertical slab gel casting cassette to abut thereat; (ii) said vertical slab gel casting cassette is a vertical flat cavity for said gel matrix to be cast therein, and said electrophoresis to take place therein, having two opposite main sidewalls, closed left and right edges, a lower opening and a U-notched upper opening; (iii) an urging mechanism for urging said cassettes and said upper buffer chamber to water-tightly abut to each other, so as to form a cassette/upper buffer chamber complex with said U-notched upper openings exposing into it; (iv) a lower buffer chamber having base plate and side walls for rooming a lower pH buffer solution, a lower electrode, and said cassette/upper buffer chamber complex therein; (v) a nonessential heat absorbing device for absorbing the Joule-heat during electrophoreses running upon requirement; and (vi) some step and method for insuring said gel matrix to be cast into said vertical slab gel casting cassettes without leakage; wherein the improved step and method for insuring said gel matrix to be cast into said vertical slab gel casting cassettes without leakage including: (a) providing a method to snugly encase a certain number of said vertical slab gel casting cassette into a membrane pouch, but leaving the upper mouth of said pouch open; (b) sandwiching the pouch snugly wrapped cassette(s) between a pair of splint, thereupon said cassettes are ready for said gel casting; whereby disclosed step and method are simple, convenient, flexible and dependable.
 16. The electrophoresis cell and method of claim 15 wherein said method including: (a) placing a certain number of said vertical slab gel casting cassette into a roomy plastic membrane pouch, which has a lower softening point; (b) using a holding means to hold the open mouth area of said pouch at the position beyond the upper edges of said cassettes; (c) exposing said pouch along with said cassettes to a temperature, which is just high enough to cause said pouch shrinking, hence said pouch snugly wraps around said cassette(s); (d) removing said holding means, thereupon said cassettes are ready for the next step of said gel casting; whereby disclosed method is good for encasing any sized cassettes for gel casting.
 17. The electrophoresis cell and method of claim 15 wherein said method including: (a) using a stretching means to stretch up an elastic membrane pouch until it is expanded wide enough; (b) placing a certain number of said vertical slab gel casting cassette into said expanded elastic membrane pouch; (c) removing said stretching means, allowing said elastic pouch to shrink and to snugly wrap around said cassettes, thereupon said cassettes are ready for the next step of said gel casting; whereby disclosed method can also be used to cast the gradient gels, provided the employed elastic membrane pouch has a tail tubule at the bottom.
 18. The electrophoresis cell and method of claim 15 wherein said method including: (a) placing two pieces of said vertical slab gel casting cassette into a size appropriate ordinary plastic membrane pouch; (b) arranging said two cassettes being side by side in said pouch, (c) using a propping means, such as a plastic stick or a plastic card, from outside to rest on said pouch along its central line; (d) using said propping means as a inflection point to fold up said pouch until said two cassettes from side by side become face to face, thereupon said two cassettes are ready for the next step of said gel casting; whereby disclosed method also can be utilized to encase more cassettes for gel casting; such as putting three cassettes into a wider pouch, using two propping means, and making a Z-shaped folding, etc.
 19. The electrophoresis cell and method of claim 15 wherein said method including: (a) placing a certain number of said vertical slab gel casting cassette into a roomy plastic membrane pouch; (b) moving said cassettes toward one side of said pouch; (c) using a propping means, such as a plastic stick or the folded edge of a plastic card, from outside to rest on said pouch at the position as close as to said cassettes; (d) using said propping means as a inflection point to fold the remaining portion of said pouch onto the cassette side, and to hold it in such a folding state, thereupon said cassettes are ready for the next step of said gel casting; whereby disclosed method can also be used to cast the gradient gels, provided the employed plastic membrane pouch has a tail tubule at the bottom.
 20. An improved vertical slab gel electrophoresis cell and method for performing electrophoresis vertically within uprightly oriented slab shaped gel matrixes comprising: (i) an upper buffer chamber for rooming an upper pH buffer solution and an upper electrode, having base plate, sidewalls and two opposite U-shaped side openings, each of them has a U-shaped rubber sealing-gasket attached alongside it, so as to allow a vertical slab gel casting cassette to abut thereat; (ii) said vertical slab gel casting cassette is a vertical flat cavity for said gel matrix to be cast therein, and said electrophoresis to take place therein, having two opposite main sidewalls, closed left and right edges, a lower opening and a U-notched upper opening; (iii) a urging mechanism for urging said cassettes and said upper buffer chamber to water-tightly abut to each other, so as to form a cassette/upper buffer chamber complex with said U-notched upper openings exposing into it; (iv) a lower buffer chamber having base plate and side walls for rooming a lower pH buffer solution, a lower electrode, and said cassette/upper buffer chamber complex therein; (v) a nonessential heat absorbing device for absorbing the Joule-heat during electrophoreses running upon requirement; and (vi) some step and method for insuring said gel matrix to be cast into said vertical slab gel casting cassettes without leakage; wherein the improvement including that the U-shaped rubber sealing-gasket employed in some embodiments of the present invention is formed by a kind of elastic rubber tubing that has an 8-shaped cross-section; whereby formed rubber sealing-gasket has higher compressibility and elasticity, therefore makes the electrophoresis cell being compatible with thickness different cassettes. 